Chapter 7 Computers and Aviation
Antony Jameson
Department of Aeronautics and Astronautics, Stanford University
Stanford, US
Although animal flight has a history of 300 million years, serious thought about human flight
has a history of a few hundred years, dating from Leonardo da Vinci,1 and successful human
flight has only been achieved during the last 110 years. This is summarized in the attached
figures 7.1-7.4. To some extent, this parallels the history of computing. Serious thought about
computing dates back to Pascal and Leibnitz. While there was a notable attempt by Babbage
to build a working computer in the 19th
century, successful electronic computers were finally
achieved in the 40s, almost exactly contemporaneously with the development of the first
successful jet aircraft. The early history of computers is summarized in figures 7.5-7.8.
Tables 7.1 and 7.2 summarize the more recent progress in the development of
supercomputers and microprocessors.
Although airplane design had reached quite an advanced level by the 30s, exemplified by
aircraft such as the DC-3 (Douglas Commercial-3) and the Spitfire (figure 7.2), the design of
high speed aircraft requires an entirely new level of sophistication. This has led to a fusion of
engineering, mathematics and computing, as indicated in figure 7.9.
Figure 7.1a Orville and Wilbur Wright,
1903 (Courtesy of USAF, United States Air
Force).
Figure 7.1b The Wright Flyer, 1903 (Courtesy
of John T. Daniels, Library of Congress, US).2
1 L. da Vinci, Notebooks, Oxford University Press, 2008
2 The Wright Flyer is the first successful powered aircraft, designed and built by the Wright brothers. They flew
it four times near Kill Devil Hills, about four miles south of Kitty Hawk, North Carolina, US.
Figure 7.2a Douglas DC-3, 1935 (Courtesy
of Douglas Aircraft, The Boeing Company).
Figure 7.2b Supermarine Spitfire, 1936 (Courtesy
of Franck Cabrol, GNU Free Documentation).
Figure 7.3a Messerschmitt ME-262, 1941
(Courtesy of USAF, United States Air Force).
Figure 7.3b Lockheed SR-71, 1964
(Courtesy of Judson Brohmer, USAF).
Figure 7.4a Boeing 747, 1969 (Courtesy of
Andre Chan, Stanford University, US).
Figure 7.4b Airbus 380, 2005 (Courtesy of
Andre Chan, Stanford University, US).
Figure 7.5a Pascal’s Pascaline, 1642
(Courtesy of André Devaux, Calmeca, France).
Figure 7.5b Leibniz’s stepped reckoner, 1672.3
Figure 7.6a Babbage’s difference engine, 1822
(Courtesy of Jitze Couperus, Flickr).
Figure 7.6b Babbage’s analytic engine, 1822
(Courtesy of Bruno Barral, Wikypedia).
Figure 7.7a Mark I, 1944 (Courtesy of John Kopplin
and Michael Rothstein, Kent State University, US).4
Figure 7.7b Cray-1, 1976 (Courtesy of
Cray Research, US).5
Figure 7.8a NEC Earth Simulator, 2002 (Courtesy of
JAMSTEC, Japan Agency for Marine-Earth Science and
Technology).
Figure 7.8b IBM Blue Gene, 2005 (Courtesy
of Argonne National Laboratory, US).
3 J. A. V. Turck, Origin of Modern Calculating Machines, The Western Society of Engineers, p.133, 1921
4 Mark I, a computer which was built as a partnership between Harvard and IBM in US, was the first
programmable digital computer made in the US. But it was not a purely electronic computer. 5 The Cray-1 was a supercomputer designed, manufactured and marketed by Cray Research founded in 1972 by
computer designer Seymour Cray in Seattle, Washington, US, After the Cray Research purchase in 2000, Cray
was formed: www.cray.com.
During the last five decades, computers have fundamentally transformed every aspect of
aviation and aerospace. These impacts fall into three main classes. First, computing has
completely transformed the design and manufacturing processes. Second, the advent of
microprocessors with ever increasing power has transformed the actual aircraft and spacecraft
themselves, with computers taking over every aspect of the flight control and navigation
systems. This parallels similar developments in automobiles, which are no longer directly
controlled by their drivers, but instead use microprocessors to optimize engine performance
and manage functions such as anti-skid breaking. The third way in which computers have
transformed aviation is that the major aspects of aircraft operations are now controlled by
computing systems such as electronic reservation and ticketing systems and automatic check-
in. We shall discuss each of these aspects in more detail in the following sections.
Table 7.1 Supercomputers timeline
Year Model Performance 1964 CDC 6600 3 MFLOPS
6
1976 Cray-1 250 MFLOPS
1993 Fujitsu Numerical Wind Tunnel 124.5 GFLOPS
2002 NEC Earth Simulator 35.86 TFLOPS
2007 IBM Blue Gene/L 478.2 TFLOPS
2009 Cray Jaguar 1.759 PFLOPS
2012 IBM Sequoia 20 PFLOPS
Table 7.2 Microprocessor timeline
Year Model Manufacturing Process Transistor Clock Bits Core 1971 Intel 4004 10 μm 2,250 108 kHz 4 1
1978 Intel 8086 3 μm 29,000 4.77 MHz 16 1
2000 Intel Pentium IV 0.18 μm 42 M 1.5 GHz 32 1
2008 Intel Core i7 45 nm 774 M 2.993 GHz 64 4
Figure 7.9 Fusion of flight experiments, mathematics and computing.
6 In computing, FLOPS (FLoating-point Operations Per Second) is a measure of computer performance, useful
in fields of scientific calculations that make heavy use of floating-point calculations. For such cases it is a more
accurate measure than the generic instructions per second.
7.1 Computing in structural and aerodynamic analysis
The first inroads of computing in the aerospace industry were in the design process,
beginning with structural analysis based on the finite element method. In fact, the origins of
the finite method may be found in the aerospace industry, in The Boeing Company, where it
was developed under the leadership of Turner in the period 1950 - 1962.7 Important early
contributions were made by Argyris who was a consultant to Boeing.8,9,10,11
The NASTRAN
(NASA STRucture ANalysis) software for structural analysis was developed under NASA
(National Aeronautics and Space Administration) sponsorship between 1964 and 1968, and
became a standard tool.
Computing methods for aerodynamic analysis follows soon behind, giving birth to the new
discipline of CFD (Computational Fluid Dynamics). The Aerodynamic Research Group of
the Douglas Aircraft Company,12
led by Smith, developed the first panel method for three
dimensional, linear, potential flows in 1964.13
Nonlinear methods were needed to enable the
prediction of high speed transonic and supersonic flows. A major breakthrough was
accomplished by Murman and Cole in 1970, who demonstrated for the first time that steady
transonic flows could be computed economically. The first computer program that could
accurately predict transonic flow over swept wings, FLO22, was developed by Jameson and
Caughey in 1975, using an extension of the method of Murman and Cole, and rapidly came
into widespread use. At this time (1976), swept wing calculations challenged the limit of the
available computing resources. The most powerful computer available, the Control Data
6600, had 131,000 words of memory. This was not enough to store a full three-dimensional
solution, which had to be read back and forth from disk drives. It had a peak computational
speed of about 3 Megaflops, and a complete swept wing calculation took about 3 hours with a
cost around 3,000 dollars. Nevertheless, Douglas found it worthwhile to run 6 or more
calculations using FLO22 every day. The first major application was the wing design of the
C17 (Cargo aircraft model 17). FLO22 was also used for the wing design of the Canadair
Challenger. This was the first application of CFD to the wing design of a commercial aircraft.
FLO22 is still used today for preliminary design studies. It is useful in this role, as the
calculations can now be performed in 10 seconds with a laptop computer.
With the advent of the first supercomputers in the early 80s, exemplified by the Cray-1,
which achieved sustained computational speeds of around 100 Megaflops, it became feasible
to solve the full fluid flow equations (the Euler equations for inviscid flow and the Navier-
Stokes equations for viscous flow) for complex configurations. The first Euler solution for a
7 M.J. Turner et al., Stiffness and deflection analysis of complex structures, Journal of the Aeronautical Sciences,
Volume 23, N. 9, p. 805, 1956 8 J.H. Argyris, The open tube: A study of thin-walled structures such as interspar wing cut-outs and open-
section stringers, Aircraft Engineering and Aerospace Technology, Volume 26, Issue 4, p. 102, 1954 9 J.H. Argyris, Flexure-torsion failure of panels: A study of instability and failure of stiffened panels under
compression when buckling in long wavelengths, Aircraft Engineering and Aerospace Technology, 26, p. 174,
1954 10
J.H. Argyris, Energy theorems and structural analysis: A generalized discourse with applications on energy
principles of structural analysis including the effects of temperature and non-linear stress-strain relations,
Aircraft Engineering and Aerospace Technology, Volume 26, Issue 11, p. 383, 1954 11
J.H. Argyris and S. Kelsey, Energy theorems and structural analysis: A generalised discourse with
applications on energy principles of structural analysis including the effects of temperature and nonlinear
stress-strain relations, Butterworth, 1960 12
The Douglas Aircraft Company was an American aerospace manufacturer based in Southern California. It
was founded in 1921 by Sr. Donald Wills Douglas and later merged with McDonnell Aircraft in 1967 to form
McDonnell Douglas: www.mdc.com 13
J.L. Hess and A.M.O. Smith, Calculation of the non-lifting potential flow about arbitrary three dimensional
bodies, Douglas Aircraft Report, N. E.S. 4062, 1962
complete aircraft was accomplished by Jameson, Baker and Weatherill in late 1985, who
were provided remote access to a Cray-1 by the Cray company.14
By the 90s, computer
performance had advanced to the point where Navier-Stokes simulations could be routinely
performed using meshes containing several million cells. This period saw the emergence of
NASA developed codes such as OVERFLOW (OVERset grid FLOW solver), CFL3D
(Computational Fluids Laboratory Three-Dimensional), USM3D (Unstructured Mesh Three-
Dimensional) and FUN3D (Fully Unstructured Navier-Stokes Three-Dimensional). During
the 80s and 90s, there was a parallel development of commercial CFD software targeted at a
wide range of industrial applications. The first commercial CFD software was Spalding’s
PHOENICS (Parabolic Hyperbolic Or Elliptic Numerical Integrated Code Series) code.
Fluent, CFX15
and STAR-CD (Simulation of Turbulent flow in Arbitrary Regions
Computational Dynamics) emerged as the most widely used commercial software packages,
but most aerospace companies still prefer to use codes specifically developed for high speed
flow simulations.
The current use of CFD in aircraft design is illustrated in figures 7.10-7.11. Figure 7.10
shows a simulation of the compressible viscous flow over an Airbus A380. Figures 7.11a and
7.11b illustrate the extent of CFD use in the designs of the A380 and the Boeing 787.
Figure 7.10 CFD simulation of A380 (Courtesy of DLR, the German Aerospace Centre).
16
Figure 7.11a CFD contributions to A380
(Courtesy of DLR). 17
Figure 7.11b CFD contributions to B787
(Courtesy of The Boeing Company) .18
7.2 Computer aided design and manufacturing
Historically, engineering parts have been defined by engineering drawings and ‘blueprints’.
These required meticulous preparation by large teams of draftsman working at drawing
boards. By the 60s, it was apparent that there was an opportunity for significant cost
reductions if this process could be computerized. This required, however, the development of
a new set of mathematical tools which provide the foundations of modern computational
geometry, and have enabled the development of CAD (Computer Aided Design) and CAM
(Computer Aided Manufacturing) systems.
14
www.cray.com 15
Fluent and CXF are computational fluid dynamics software marketed by Ansys Corporation:
www.ansys.com. 16
DLR (Deutsches Zentrum für Luft- und Raumfahrt e.V.): www.dlr.de 17
Ibidem 18
www.boeing.ch
The early development of geometric modelling technology was driven by the automotive and
aircraft industries due to their unique engineering requirements for a wide range of curves
and surfaces for their parts. Manually defining and manufacturing these components was
becoming increasingly time-consuming and costly. By the early 60s, numerically controlled
machine tools became more readily available. There was the need to generate the digital
information to drive these machines. CAD systems began to emerge in this era. Some of the
first development took place at Citroën where de Casteljau developed CAD methods, and
introduced the de Casteljau algorithm in reports that were not published outside Citroën,19,20
and at Renault, where Bézier led the development of the UNISURF system,21
and introduced
the concept of the Bézier curve.22,23,24
As in the case of CFD, CAD system development also experienced rapid changes as
computer hardware became more capable. In the 60s, CAD software was run on mainframe
computers. The earliest CAD systems were used primarily for replacing the traditional
drafting practice. Though limited at that time to handle only two-dimensional data, using
CAD for engineering drawing helped to reduce drawing errors and allowed the drawings to
be modified and reused. Large aerospace and automotive companies with the resources to
cover the high costs of early computers became the earliest users of CAD software. Most
CAD development in that period was conducted internally in those companies. An example
was the CADAM (Computer-Augmented Design And Manufacturing) system developed by
the Lockheed25
aircraft company. This system, which automated the production of two-
dimensional drawings was marketed by Lockheed after 1972. Dassault purchased a license in
1974, and also acquired UNISURF from Renault in 1976. Subsequently, this evolved into the
three-dimensional modelling system CATIA (Computer Aided Three-dimensional Interactive
Application), which was originally used in conjunction with CADAM. Dassault began
marketing CATIA in 1981, and it has become the most widely used CAD tool in the
aerospace industry. In the 70s, the emergence of powerful minicomputers made CAD
software more affordable and accessible, and helped create the commercial CAD software
market. Very rapid growth of commercial CAD changed the way CAD was used and
developed in big automotive and aerospace companies as they began to use commercial
software in conjunction with their internally developed CAD systems. Simultaneously, there
were significant advances in the geometric algorithms that CAD software was based on,
including B-Spline (Basis Spline),26,27
and NURBS (Non-Uniform Rational B-Spline).28
In
the 80s, low-cost, low-maintenance, and high-performance workstations using UNIX29
operating system were introduced. This again revolutionized the CAD software market, and
effectively replaced the mainframe and mid-range computers as the preferred hardware for
19
P. de Casteljau, Outillages méthodes calcul, Technical report, André Citroën Automobiles SA, 1959 20
P. de Casteljau, Courbes et surfaces à pôles, Technical report, André Citroën Automobiles SA, 1963 21
UNISURF was a pioneering surface system, designed to assist with car body design and tooling, developed in
1968, and full in use at the company in 1975. By 1999, around 1,500 Renault employees made use of it. 22
A. Bézier curve is a parametric curve frequently used in computer graphics and related fields. 23
P. Bézier, Définition numérique des courbes et surfaces I, Automatisme, 11, N. 12, p. 625, 1966 24
P. Bézier, The mathematical basis of the UNISURF CAD system, Butterworth-Heinemann, 1986 25
Lockheed, the Lockheed Corporation (originally Loughead Aircraft Manufacturing Company) was an
American aerospace company founded in 1912 and later merged with Martin Marietta to form Lockheed Martin
in 1995. 26
In mathematics, a Basis Spline is a sufficiently polynomial function with derivatives of all orders that is
defined by multiple subfunctions. 27
R. Risenfeld, Applications of B-Spline Approximation to Geometric Problems of CAD, Ph.D. thesis, Syracuse
University, 1973 28
K.J. Versprille, Computer-Aided Design Applications of the Rational B-Spline Approximation Form, Ph.D.
thesis, Syracuse University, Italy, 1975 29
Originally UNICS, UNiplexed Information and Computing System
CAD systems. At the same time, three-dimensional CAD software and solid modelling
techniques matured and became a commercial reality. As the computer hardware and
maintenance costs continued to fall and CAD software became more available and powerful,
commercial CAD systems spread throughout industry.
In 1988, Boeing made the decision to use the commercially available CATIA to design and
draft the new B777 airplane, which became the first CAD based ‘paperless’ design of a
commercial aircraft. This decision proved to be very successful, leading to reduced product
development time and cost. From the 90s to the present time, the same trend repeated itself,
with more cost-effective and powerful personal computers replacing the less cost-effective
workstations, and with a corresponding migration of CAD software from the UNIX system to
the mainstream Windows and Linux operating systems. The function of CAD systems also
evolved from pure geometric modelling tools into a system of computer aided engineering
solutions that consists of computer aided manufacturing, digital assembly, and virtual
production management.
Using information technology such as computer aided manufacturing and production can
effectively restore close interaction and communication among a large number of people in
the design process. In a computer assisted environment, the airplane designer has access to
manufacturing processes and tools in the form of virtual environments. These will allow the
designer to virtually manufacture the product while designing it. A more optimal design trade
and resource allocation between production and airplane performance can be achieved early
in the design stage.
To conclude this section, some statistics are presented from the study of the digitally
designed Boeing 777, which demonstrate the great benefits from design automation achieved
through CAD system. Boeing used CAD systems that combined geometric modelling using
CATIA, finite element analysis using ELFINI (Finite Element Analysis System) and digital
assembly using EPIC (Electronic Preassembly Integration on CATIA). The CAD systems
allowed Boeing engineers to simulate the geometry of an airplane design on the computer
without the costly and time-consuming investment of using physical mock-ups. More than 3
million parts were represented in an integrated database. A complete 3D virtual mock-up of
the airplane was created. This allowed the designers to investigate part interferences,
assembly interfaces and maintainability using spatial visualizations of the aircraft
components. The consequences were dramatic. In comparison with the earlier aircraft design
and manufacturing processes, Boeing eliminated more than 3000 assembly interfaces without
any physical prototyping, and achieved 90 percent reduction in engineering change requests,
50 percent reduction in cycle time for engineering change request, 90 percent reduction in
material rework, and 50 times improvement in assembly tolerances for fuselage. Overall,
CAD/CAM systems and digital pre-assembly greatly improve the quality of airplane designs
and reduce the time required to introduce new airplanes into the marketplace. The application
of CAD in the design of the Boeing 777 is illustrated in figure 7.12.
3D Fly-Thru Full-Motion Human Modelling
Digital Pre-Assembly of a Boeing Airplane
Figure 7.12 CAD applications in aircraft design and manufacturing (Courtesy of CATIA,
Computer Aided Three-dimensional Interactive Application).
7.3 Fly-By-Wire and other on-board systems
Early high performance computers were far too bulky and heavy to be carried on-board an
aircraft, and consequently the role of computers was limited to functions that could be
performed on the ground, such as design and manufacturing. The advent of the modern
microprocessor has completely changed the situation. A processor such as an Intel Core i7
with 4 cores clocked at 2.7 GHz is just as powerful as the supercomputers of the 80s. Hence,
it is now possible to computerize critical on-board functions such as control, guidance,
navigation, and collision avoidance. In particular, the development of digital FBW (Fly-By-
Wire) systems has revolutionized the operation of both military and commercial aircraft. The
General Dynamics F16 was the first Fighter military aircraft with a full digital FBW control
system. Led by Ziegler, a former fighter pilot, Airbus was the first company to use Fly-By-
Wire for civil aircraft, the Airbus A320. Soon after FBW control systems were adopted for
the Airbus 330 and 340, and the Boeing 777. The FBW control system has been credited with
a key role in the successful descent of an Airbus 320 on the Hudson River with both engines
out after a bird strike.
In a FBW system digital controls replace the conventional mechanically operated flight
controls. The elimination of mechanical components in the new digital system is clearly
illustrated in figure 7.13. The pilot no longer physically moves the control surfaces through
mechanical linkages. Instead the pilot’s commands, or the orders from the autopilot
computers (when in autopilot mode) are transmitted digitally to a group of flight computers
which instantly interpret and analyse the control inputs and evaluate the aircraft’s speed,
weight, atmospheric conditions, and other variables to arrive at the optimum control
deflections. The flight control surfaces are then moved by actuators which are controlled by
the electrical signals. The replacement of the conventional mechanical components with
electrically transmitted signals along wires leads to the name FBW. Realization of the FBW
system is not possible without the development of digital flight computers and
microprocessors that enable a fail-safe flight control system to be implemented economically,
safely, and reliably.
Figure 7.13 Schematic of a digital FBW system.
30
The flight computers take in all the information including pilot’s order, the aircraft’s current
state and its external environment, and move the control surfaces to follow the desired flight
path while at the same time achieve good handling quality and make sure the airplane is not
over-stressed beyond its flight envelope. There are multiple computers for redundancy.
Sophisticated voting and consolidation algorithms help to detect and isolate failures in the
event of faults occurring in any of the actuators. Another advantage of digital FBW actuation
is the faster control surface position feedback that significantly increases actuation response
speed. Fast FBW system response is crucial for keeping aerodynamically unstable airplane
from divergence. An extreme example is the Lockheed F117 stealth fighter, which could fly
for about 1/10 second if it were not for its FBW system. In commercial aircraft, FBW
systems allow the use of smaller tail surfaces with a consequent reduction in both weight and
drag.
7.4 Airborne software
While Fly-By-Wire systems are one of the most visible uses of on-board digital system,
airborne software is now used to control almost every function of both military and
commercial aircraft. The Block 3 software for the Lockheed F35 fighter is planned to have
8.6 million lines of code written in C and C++.3132
This will be used to provide a complete
fusion of the flight control systems with the battlefield awareness systems. The first use of
30
R.P.G. Collinson, Introduction to Avionics Systems, 2nd
Edition, Kluwer Academic Publishers, 2003 31
C++ is a programming language that is general purpose, developed by Bjarne Stroustrup starting in 1979 at
Bell Laboratories (formerly known as American Telephone & Telegraph, AT&T, Bell Laboratories). It was
originally named C with Classes, adding object oriented features, such as other enhancements to the general-
purpose programming language C programming language developed by Dennis Ritchie between 1969 and
1973at AT&T Bell Laboratories. 32
G. Warwick, Flight Tests Of Next F-35 Block Underway, Aviation Week and Space Technology, 2010
airborne software in a commercial aircraft was the Litton LTN-5133
Inertial Navigation
System on the Boeing 707 in 1968.34
Since then, it has been growing rapidly with each new
generation of commercial aircraft, as microprocessors with ever increasing power have
become available. Two and a half million lines of code were newly developed for the Boeing
777 in the ADA language.35,36
Including commercial-off-the-shelf software, the B777 has
more than 4 million lines of airborne software. The FAA (Federal Aviation Administration)
has developed standards for the certification of airborne software. Modern commercial
aircraft feature loadable systems that can easily be replaced or upgraded. On the Boeing 777,
these include systems such as the EEC (Electronic Engine Control), the ADM (Air Data
Monitor), the CSDS (Cargo Smoke Detector System), the PFC (Primary Flight Computer),
the GPSSU (Global Positioning System Sensor Unit) and the SATCOM (Satellite
communications) system.
Airborne collision avoidance systems are a particularly important example of airborne
software. The current standard is the TCAS (Traffic Alert and Collision Avoidance System).
However, the Lincoln Laboratory at the MIT (Massachusetts Institute of Technology) has
been developing advanced algorithms during the last few years which have been incorporated
in the new ACAS X (Airborne Collision Avoidance System X),37
and the FAA is undertaking
trials with the aim of making this the new standard.
7.5 Ground based computer systems
Ground based computers of very large capacity are now used to control every aspect of
commercial aviation. The ATC (Air Traffic Control) system is heavily dependent on
computers. There are around 7,000 aircraft in the air over the United States at times of peak
traffic, as illustrated in figure 7.14b. Computers are needed for safety, efficiency and to
enable increased capacity.
Computer systems are equally crucial to airline management and operations. As passengers,
we have all experienced electronic reservation systems. The first such system, named
‘SABRE’ (Semi-Automated Business Research Environment), was a joint development of
American Airlines and IBM. After its introduction in 1964, other airlines soon followed suit.
Today, each airline’s computer reservation system interfaces with one of several GDS
(Global Distribution System). The major GDS providers are Amadeus,38
Travelport,39
and
Sabre.40
Computer systems are also used for online flight tracking. In addition, the airlines
use yield management systems which adjust ticket prices from minute to minute, taking
account of factors such as the number of unsold seats and the time to departure, with the aim
of maximizing the revenue yield of each flight.
33
Litton LTN-51 was an inertial navigation system developed by Litton Industries now part of Northrup
Grumman Corporation: www.northropgrumman.com. 34
J.P. Potocki de Montalk, Computer software in civil aircraft, Microprocessors and Microsystems, Volume 17,
Issue 1, p. 17, 1993 35
ADA is a structured and object-oriented high-level computer programming language originally designed by a
team led by Jean Ichbiah of CII Honeywell Bull (now Bull: www.bull.com) under contract to the US DoD
(Department of Defense) from 1977 to 1983. It was named after Ada Lovelace (1815–1852), who is credited as
being the first computer programmer. 36
R.J. Pehrson, Software development for the Boeing 777, The Boeing Company, Technical Report, 1996 37
M.J. Kochenderfer et al., Next-Generation Airborne Collision Avoidance System, Lincoln Laboratory Journal,
Volume 19, N. 1, p. 17, 2012 38
www.amadeus.com 39
www.travelport.com 40
www.sabre.com
Figure 7.14a Air traffic control chart. Figure 7.14b Aircraft movement at peak traffic.
(Courtesy of FAA, Federal Aviation Administration)
7.6 Conclusion
The external appearance of long range commercial aircraft has not changed much during the
last 50 years, since the introduction of the first jet transports around 1960, reflecting the
qualitative understanding of swept wing design that had been achieved by aerospace
engineers. The design process, however, has been completely revolutionized during the same
period by the systematic use of computational simulation. Moreover the role of information
technology now extends well beyond the design and manufacturing process to the actual
flight operations and management, through technologies such as digital FBW. Looking to the
future, these trends will inevitably continue. According to the forecasts of Boeing and Airbus,
air traffic is likely to continue growing at close to 5 percent per year for the next 20 years to
more than double its current levels, with about twice as many aircraft in service. This will
lead to increasingly severe environmental impacts in both emissions and community noise.
Consequently, the European Union has announced an Aeronautics 2020 Vision which calls
for
50 percent cut in CO2 emission per passenger kilometre.
80 percent cut in nitrogen oxide emission.
50 percent cut in airplane drag.
50 percent cut in perceived noise.
These targets are not likely to be realized without the pervasive use of advanced
computational simulations. A major challenge is in aero-acoustics, paced by the demand to
reduce the noise signature of both take-off and landing operations. The prediction of airframe
noise due to high lift systems and landing gear remains in tractable with current
computational methods, and will probably require a combination of high order numerical
algorithms with massively parallel computation at the exascale.
On the operational side, there is tremendous interest in unmanned air vehicles (UAVs) for
both military and civil applications. To date, the majority of UAVs, such as the Predator
drone, are remotely piloted by human operators based in ground stations. In the future, we
will see increasing use of autonomous UAVs, able to fly completely pre-programmed
missions without human intervention. Autonomous UAVs can greatly reduce the cost of
surveillance and remote sensing operations, and actually enable them in inhospitable
environments such as thunderstorms. While it is not clear how soon passengers may be
willing to fly in aircraft without pilots on board, the technology already exists for
autonomous unmanned cargo operations, if the issues of the integration of UAVs into the air
traffic control system can be satisfactorily resolved. In fact, unmanned operations may
actually prove to be safer, given that pilot errors are one of the main causes of airplane
crashes. The use of autonomous UAVs for customer deliveries is already being envisaged by
companies such as Amazon.
Overall, we can anticipate that the future will see an increasing penetration of autonomous
UAVs into all aspects of aviation, including novel surveillance and transportation systems.
The emergence of autonomous UAVs represents the ultimate fusion of the technologies of
computing and flight. Such machines may ultimately be able to match the capabilities already
achieved in nature by insects and birds.